Perilymph Kinetics of FITC-Dextran Reveals Homeostasis Dominated by the Cochlear Aqueduct and Cerebrospinal Fluid

Salt, Alec N.; Gill, Ruth; Hartsock, Jared J.

doi:10.1007/s10162-015-0512-1

Cited by 41 publications

(47 citation statements)

References 28 publications

(22 reference statements)

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“…It has been shown that drug delivery in rodent cochlea is much more effective when injected through the semicircular canal than through the round window, because rodents have a large cochlear aqueduct, which is located at the base of the cochlea, next to the round window. 37,38 The AAV8-whirlin delivered through the round window may be diluted by cerebrospinal fluid from the cochlear aqueduct, or it may escape through the cochlear aqueduct, which decreases its concentration and limits its ability to infect the entire cochlea. 38 When AAV8-whirlin gene therapy was delivered through the posterior semicircular canal, the average IHC stereocilia lengths in the eight whirler mice that showed hearing recovery were much longer than in our previous study in which AAV8-whirlin was injected through the round window.…”

Section: Discussionmentioning

confidence: 99%

“…37,38 The AAV8-whirlin delivered through the round window may be diluted by cerebrospinal fluid from the cochlear aqueduct, or it may escape through the cochlear aqueduct, which decreases its concentration and limits its ability to infect the entire cochlea. 38 When AAV8-whirlin gene therapy was delivered through the posterior semicircular canal, the average IHC stereocilia lengths in the eight whirler mice that showed hearing recovery were much longer than in our previous study in which AAV8-whirlin was injected through the round window. 14 This is likely due to the significantly higher number of hair cells with whirlin expression achieved in the present study (the AAV8-whirlin used in this study is the same as in our previous study).…”

Section: Discussionmentioning

confidence: 99%

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Gene Therapy Restores Balance and Auditory Functions in a Mouse Model of Usher Syndrome

et al. 2017

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Gene Therapy Restores Balance and Auditory Functions in a Mouse Model of Usher Syndrome

et al. 2017

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“…In the guinea pig, cerebrospinal fluid (CSF) entry into the scala tympani through the cochlear aqueduct has been described to have a diluting effect on substances delivered through the round window. This dilution has been theorized to derive both from entry of CSF into the scala tympani and from loss of drug into the CSF space (24), with CSF entering at a very slow rate in a sealed, normal cochlea (24,25). This likely contributes to the slow, apically-directed flow within the normal guinea pig cochlea, measured to be approximately 1.6 nL/min (25).…”

Section: Discussionmentioning

confidence: 99%

Intracochlear Drug Delivery Through the Oval Window in Fresh Cadaveric Human Temporal Bones

Kang

Nguyen

McKenna

et al. 2016

Otology &Amp; Neurotology

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Hypothesis Drug delivered to the oval window can diffuse to the apex of the human cochlea. Background We have previously demonstrated that zoledronate, a nitrogen-containing bisphosphonate, can arrest the sensorineural hearing loss in cochlear otosclerosis. We have also shown that, in animals, delivery of bisphosphonate into the cochlea can dramatically increase delivery efficiency. Intracochlear drug delivery has the potential to increase local concentration of drug while decreasing the risk of systemic toxicity. In the present study, a fluorescently labeled bisphosphonate compound (6-FAM-ZOL) was introduced into the human cochlea through the oval window and its distribution within the temporal bone was quantified. Methods In three fresh human temporal bones, we introduced 6-FAM-ZOL via the oval window. We compared these specimens to control specimens treated with artificial perilymph alone. Specimens were then processed, embedded into methyl methacrylate, and ground to the mid-modiolar axis. We quantified the fluorescence in confocal images. Results We found 6-FAM-ZOL to be distributed up to the apical cochlear turn. In specimens treated with 6-FAM-ZOL, we identified a strong baso-apical gradient of fluorescent signal along the lateral cochlear wall and the modiolus both in the scala vestibuli and in the scala tympani. Conclusions Bisphosphonate introduced via the oval window in the human cochlea can be delivered up to the apical cochlear turn. Inter-scalar communication is likely to play an important role in determining patterns of drug delivery in the inner ear.

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“…Constant-rate injections, which were not used, would have yielded reduced flow rate as scala tympani cross section widens. Dilution of solution concentration from mixture with cerebrospinal fluid (CSF) that enters through cochlear aqueduct is one of several reasons why the common procedure of round window niche applications cannot treat the entire cochlear length (Salt et al 2015). In contrast to drug delivery at the cochlear base, apical injections avoid dilutions even at the lower range of injection rates (i.e., 25 nl/min) which are close to the measured sustained volume of cerebrospinal fluid entry of ~30 nl/min through the cochlear aqueduct (cf.…”

Section: Methodsmentioning

confidence: 99%

“…In contrast to drug delivery at the cochlear base, apical injections avoid dilutions even at the lower range of injection rates (i.e., 25 nl/min) which are close to the measured sustained volume of cerebrospinal fluid entry of ~30 nl/min through the cochlear aqueduct (cf. Salt & DeMott 1998, Salt et al 2015). Thus, from the start of the injection thereafter, the entry of cerebrospinal fluid at the base will be suppressed.…”

Section: Methodsmentioning

confidence: 99%

Drug delivery into the cochlear apex: Improved control to sequentially affect finely spaced regions along the entire length of the cochlear spiral

Lichtenhan

Hartsock

Dornhoffer

et al. 2016

Journal of Neuroscience Methods

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Background Administering pharmaceuticals to the scala tympani of the inner ear is a common approach to study cochlear physiology and mechanics. We present here a novel method for in vivo drug delivery in a controlled manner to sealed ears. New method Injections of ototoxic solutions were applied from a pipette sealed into a fenestra in the cochlear apex, progressively driving solutions along the length of scala tympani toward the cochlear aqueduct at the base. Drugs can be delivered rapidly or slowly. In this report we focus on slow delivery in which the injection rate is automatically adjusted to account for varying cross sectional area of the scala tympani, therefore driving a solution front at uniform rate. Results Objective measurements originating from finely spaced, low- to high-characteristic cochlear frequency places were sequentially affected. Comparison with existing methods(s): Controlled administration of pharmaceuticals into the cochlear apex overcomes a number of serious limitations of previously established methods such as cochlear perfusions with an injection pipette in the cochlear base: The drug concentration achieved is more precisely controlled, drug concentrations remain in scala tympani and are not rapidly washed out by cerebrospinal fluid flow, and the entire length of the cochlear spiral can be treated quickly or slowly with time. Conclusions Controlled administration of solutions into the cochlear apex can be a powerful approach to sequentially effect objective measurements originating from finely spaced cochlear regions and allows, for the first time, the spatial origin of CAPs to be objectively defined.

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Perilymph Kinetics of FITC-Dextran Reveals Homeostasis Dominated by the Cochlear Aqueduct and Cerebrospinal Fluid

Cited by 41 publications

References 28 publications

Gene Therapy Restores Balance and Auditory Functions in a Mouse Model of Usher Syndrome

Gene Therapy Restores Balance and Auditory Functions in a Mouse Model of Usher Syndrome

Intracochlear Drug Delivery Through the Oval Window in Fresh Cadaveric Human Temporal Bones

Drug delivery into the cochlear apex: Improved control to sequentially affect finely spaced regions along the entire length of the cochlear spiral

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